JPS6127241A - Manufacture of vibration insulation rubber with metal housing - Google Patents

Abstract

PURPOSE:To enable the bonding of a rubber member to metal housings to be improved even without treatment to the rubber member, by vulcanizing the rubber member partially and applying a thermoplastic or thermosetting adhesive to the surface of the rubber member. CONSTITUTION:A rubber member 6 is vulcanized partially, a thermoplastic or thermosetting adhesive 7 is applied to the surface of the rubber member 6, then the rubber member 6 is heat-treated thereby vulcanizing the rubber member 6 completely and drying the adhesive 7. Then the rubber member 6 is forced between metal housings 1, 3, and they are heated to set the adhesive 7 to join the rubber member 6 to the metal housings 1, 3. Since the thermoplastic or thermosetting adhesive is applied to the surface of the rubber member in a half vulcanized state followed by drying, the bonding strength of the adhesive to the rubber member can be increased.

Description

DETAILED DESCRIPTION OF THE INVENTION Object of the Invention (Field of Industrial Application) The present invention relates to a method of manufacturing a vibration isolating rubber with a metal housing such as a torsional damper pulley.

(Prior art) Conventional anti-vibration rubber with a metal housing is made by sufficiently vulcanizing a plate-shaped or ring-shaped anti-vibration rubber member in advance, applying an adhesive to its surface or the metal housing, and drying it. from,
The rubber member was press-fitted between the metal housings, and then the adhesive was heated and cured to adhere the rubber member to the metal housing. However, it has been difficult to obtain sufficient adhesive strength between vulcanized rubber and metal.

Therefore, various mechanical or chemical surface treatment methods have been studied as adhesive techniques for vulcanized rubber. but,
These methods have problems such as high equipment costs, the toxicity of the treatment liquid and the need for careful handling, and the need to treat waste liquid.

(Problems to be solved by the invention) As mentioned above, this invention has problems such as difficulty in obtaining sufficient adhesive strength, high equipment cost, toxicity of the treatment liquid and the need for careful handling, and treatment of waste liquid. This was done in order to solve the problems in the conventional manufacturing method of vibration isolating rubber with a metal housing, such as the need to perform the above-mentioned surface treatment, and it improves the adhesion of the rubber member to the metal housing. The present invention provides a novel method for manufacturing a vibration isolating rubber with a metal housing, which is simple in process, has excellent workability, and can reduce costs.

Structure of the Invention (Means for Solving the Problems) In order to solve the above-mentioned problems, the method for producing a vibration-proof rubber with a metal housing of the present invention semi-vulcanizes a rubber member and injects thermoplastic or thermal A step of applying a hardening adhesive, a step of heating the rubber member to completely vulcanize the rubber member and drying the adhesive, a step of press-fitting the rubber member between the metal housings, and a step of press-fitting the rubber member between the metal housings. The present invention adopts a configuration consisting of a step of bonding the rubber member to the metal housing by heating the housing and the rubber member to harden the adhesive.

(Function) Since the thermoplastic or thermosetting adhesive is applied and dried on the surface of the semi-vulcanized rubber member, the adhesive strength of the adhesive to the rubber member is increased.

(Embodiment) An embodiment of the present invention in a torsional damper pulley will be described below with reference to the drawings. In the drawing, reference numeral 1 indicates a pulley rim of a damper pulley, which is formed into a ring shape of metal. The inner circumferential surface 2 is a smooth cylindrical inner surface. Reference numeral 3 denotes an inner hub made of metal disposed inside the damper pulley 1, which is provided with a shaft hole 4 in its center, and whose outer circumferential surface 5 faces the inner circumferential surface of the damper pulley at a small distance. It has a smooth cylindrical surface.

6 is a rubber ring press-fitted and glued between the inner peripheral surface 2 of the pulley rim 1 and the outer peripheral surface 5 of the inner hub 3;
Rubbers blended in the weight parts shown below are used.

Butyl rubber 100 Zinc oxide 5 Stearic acid 1 HAF carbon black 90 Naphthenic process oil 20 Vulcanization accelerator MBTS O,5 Vulcanization accelerator TMTD 1 Sulfur 2 The above rubber ring 6 is first semi-vulcanized (semi-vulcanized) after molding. (will be described in detail later), and adhesive 7 is applied to the inner and outer circumferential surfaces thereof. Next, the rubber ring 6 is heat-treated so that the adhesive 7 dries and the rubber ring 6 is completely vulcanized. The adhesive 7 is applied again to the surface of the dried adhesive 7 and dried. Immediately before press-fitting, a press-fitting liquid 8 is applied onto the dried adhesive 7 by a dipping method. The rubber ring 6 is heated after being press-fitted to harden the adhesive 7, so that it is firmly adhered to the pulley rim 1 and the inner hub 3.

Here, the adhesive 7 can be an ordinary thermoplastic or thermosetting rubber-to-metal adhesive; for example, Chemlock 250 (trade name of Hewson Chemicals, main component is chlorinated rubber) is used. ing.

In addition, various types of press-in liquid such as process oil can be used as the press-in liquid 8, but in this example, a low-viscosity aromatic process oil (specifically, manufactured by Fuji Kosan Co., Ltd. under the trade name EPX #1) is used. It is used.

Next, a method for press-fitting and bonding the rubber ring 6 between the pulley rim 1 and the inner hub 3 in the damper pulley configured as described above will be described based on test examples.

First, the materials such as butyl rubber are kneaded and molded into a rubber ring 6 using a mold. Subsequently, the rubber ring 6 is held in the same mold at 160° C. for 2 minutes to semi-vulcanize it to the extent that the ring shape can be maintained at least. What is semi-vulcanization?
In the vulcanization curve 9 of the curelastometer shown in FIG.
Refers to the entire range in which the torque value changes from the lower limit value to the upper limit value (excluding when it is at the lower limit value or upper limit value). At this time, in the vulcanization curve 9, the torque value is the upper limit of 50
It is desirable that it be ~80%.

Next, after waiting for the rubber ring 6 to cool down, adhesive 7 is applied to its surface. Subsequently, the rubber ring 6 is held in hot air at 150° C. for one hour to dry the adhesive 7 and completely vulcanize the rubber member 6. This heating improves the adhesive force of the adhesive 7 to the rubber ring 6.

In particular, in this embodiment, since the adhesive 7 is adhered to the active rubber ring 6 in a semi-vulcanized state (in progress of vulcanization), the adhesive force is increased. Note that heating at 150° C. does not inhibit the reactivity with the adhesive to be applied next. Further, by complete vulcanization, the rubber ring 6 has enough strength to withstand press-fitting. Subsequently, after the rubber ring 6 is cooled, an adhesive 7 is further applied to its surface, and this is allowed to air dry. Some heating may be applied during this drying as well.

Next, the rubber ring 6 is immersed in the press-fitting liquid 8 (at room temperature) for 10 minutes to apply the press-fitting liquid 8 onto the adhesive 7 and dissolve the adhesive 7.

Next, as shown in FIGS. 2 to 4, the inner hub 3 is set inside the degreased pulley rim 1, and while the adhesive 7 is melting, the inner peripheral surface 2 of the pulley rim 1 and the outer peripheral surface of the inner hub 3 are During this time, the rubber ring 6 is press-fitted at room temperature. Here, the press-fitting rate (deformation rate due to press-fitting) of the rubber ring 6 is 30
%. During this press-fitting, since the adhesive 7 on the surface of the rubber ring 6 is appropriately dissolved at room temperature, the press-fitting liquid 8 and the adhesive 7 act as a lubricant. Therefore, the rubber ring 6 can be easily press-fitted at low pressure.

Next, the damper pulley that has been press-fitted is held in hot air at 200°C for a period of time to complete the curing reaction of the adhesive 7, thereby adhering the rubber ring 6 to the pulley rim 1 and inner hub 3, and then cooled to room temperature. do it.

After the damper pulley with the rubber ring 6 press-fitted and bonded as described above was left at room temperature for 24 hours, 1/8 of the entire circumference was cut off as shown in Figure 5, and the pulley rim was cut off as shown by the arrow in the figure. A tensile test was performed on the end of the pulley rim 1 and the end of the inner hub 3 at a tensile speed of 50 mm/min to measure the adhesive strength between the pulley rim 1 and the inner hub 3. At this time, the rubber ring 6 is removed from the pulley rim 1 or inner hub 3.
The adhesive strength when the film was partially peeled off was 16 ko/cm.

For comparison, the rubber ring 6 was completely vulcanized in advance.
After applying an adhesive to the surface, the adhesive strength of a comparative example in which a rubber member was press-fitted and adhered between the metal housings in the same manner as in the present example was measured and found to be 11 kQ/cm.

As is clear from the results, the adhesive strength of this example was approximately 40% higher than that of the comparative example. The reason for this is thought to be that the adhesive 7 is bonded to the activated rubber ring 6 during vulcanization, so that its adhesive strength increases.

As described above, in this embodiment, the adhesion of the rubber member to the metal housing is improved without surface treatment. In addition, there is no need for a surface treatment process, so it has excellent workability.
It is also possible to reduce costs.

It should be noted that the present invention is not limited to the configuration of the above-mentioned embodiments, but can also be embodied as follows, for example.

(1) Changing the material of the rubber ring 6 or the type of adhesive 7.

(2) Changing the type of injection fluid 8. When selecting an injection fluid, it is desirable to consider various properties such as toxicity, flammability, influence on adhesive strength, and physical properties.

(3) Before press-fitting the rubber ring 6, apply the press-fitting liquid 8 also to the inner circumferential surface 2 of the pulley rim 1 and the outer circumferential surface 5 of the inner hub 3. By doing so, the press-fitting pressure can be further lowered and the press-fitting properties can be improved.

(4) A method for manufacturing vibration-proof rubber with a metal housing other than damper pulleys.

Effects of the Invention As detailed above, the present invention can improve the adhesion of a rubber member to a metal housing without surface treatment, and the process is simple and has excellent workability, and can also reduce costs. It has excellent effects.

[Brief explanation of drawings]

Fig. 1 is a plan view showing an embodiment of the present invention in a damper pulley, Fig. 2 is an exploded perspective view, and Figs. 3 and 4 show the rubber ring in the middle of press-fitting and after press-fitting, respectively. FIG. 5 is a plan view showing the damper pulley similarly cut, and FIG. 6 is a line diagram showing the vulcanization curve of the curelastometer. Pulley rim 1, inner hub 3, rubber ring 6, adhesive 7, press-fitting fluid 8゜Patent applicant: Toyoda Gosei Co., Ltd. Representative Patent attorney On 1) Hironobu Figure 4 Figure 6 Addition of βL

Claims (1)

[Claims] 1. A step of semi-vulcanizing the rubber member (6) and applying a thermoplastic or thermosetting adhesive (7) to its surface;
The rubber member (6) is heat-treated to completely vulcanize the rubber member (6) and the adhesive (7) is dried, and the rubber member (6) is placed between the metal housings (1, 3). and a step of bonding the rubber member (6) to the metal housing (1, 3) by heating the metal housing (1, 3) and the rubber member (6) to harden the adhesive (7). A method for manufacturing a vibration-proof rubber with a metal housing, characterized by comprising the following steps. 2. The step of press-fitting the rubber member (6) between the metal housings (1, 3) involves applying an adhesive (
7) The method for manufacturing a vibration isolating rubber with a metal housing according to claim 1, characterized in that the process is carried out after applying the injection liquid (8) thereon. 3. The adhesive (7) is a rubber-to-metal adhesive mainly composed of chlorinated rubber, and the injection fluid (8) is an aromatic process oil. A method for manufacturing anti-vibration rubber with a metal housing.